Combinatorial Actions of Genetic Variants and Gender Bias of Alzherimer's Disease

PROJECT ABSTRACT Alzheimer?s disease (AD) is conventionally characterized by specific neuropathological features, including the appearance of extracellular amyloid deposits and the accumulation of intracellular neurofibrillary tangles. While several gene mutations are clearly associated with early onset Alzheimer?s disease, the large number of individuals exhibiting delayed onset, aging-associated AD, are likely to harbor many alterations in linked modifier genes that predispose to AD susceptibility. Genetic and genome wide association studies (GWAS) have identified numerous genes and risk alleles that indicate both cell autonomous and non-cell autonomous mechanisms contributing to loss of neurons and cognitive decline. In this regard, the majority of risk variants identified by GWAS reside in non-coding regions of the genome, implying that they act in part to alter gene expression. This proposal responds to the RFA indicating a particular need for approaches designed to delineate the transcriptional and cellular consequences of combinations of SNPs in the risk alleles by generating new cell line reagents to help unravel the question of the causative SNPs and their target genes in specific neurons derived from iPS cells of AD individuals. There are two features of sporadic AD that require molecular explanation- the potential role of aging in AD susceptibility, and the striking gender disparity, with the incidence of AD being exaggerated in females. These issues can only now be addressed based on new technologies and the availability of patient-derived samples. Our proposed research plan takes advantage of the invaluable samples stored at the brain bank of the Shiley-Marcos Alzheimer's Disease Research Center (ADRC) at UCSD, and the iPSC-derived neurons (Salk). This approach will interrogate the effects of different genetic variants with other risk factors (e.g. age, sex), and assess their effects on cell type-specific enhancer landscapes. By merging these data, we can begin to identify the potential causative SNPs that result in altered function of cell-type specific enhancers. We propose using a high throughput 4C screening approach (UMI-4C), and Hi-ChIP, to identify the most likely causative, enhancer-associated SNPs for functionally-implicated coding target genes. Exploiting the power of contemporary gene editing approaches in control or patient-derived iPS cells to specific neuronal cell types, and to astroglia, we can assess the transcriptional phenotypes and functional behaviors of neurons harboring different combinations of risk alleles, both in the isolated cell lines alone and in combination with coculture experiments with astroglia and microglia, as effects of these SNPs may be manifest only with astroglial:neuronal interactions. Together these studies will use powerful contemporary global genomic approaches to determine the coding transcriptional targets of several of the most significant SNPs in enhancers, and the link to roles of estrogen receptor in the gender disparity for AD.